Display device and optical device

ABSTRACT

Disclosed herein is a display device including, a visual target, and a backlight adapted to illuminate the visual target from the rear, the backlight including, a plurality of first light sources, second light sources, and a light guide plate, wherein the light guide plate has a plurality of projecting portions on a side surface portion thereof upon which the light, produced by the plurality of first and second light sources is incident, the projecting portions being arranged, along the side surface portion and project toward the one side of the given direction, the plurality of first light sources are disposed to be opposed to the tip surfaces of the plurality of projecting portions, and the second light sources are disposed to be opposed to the bottom surfaces of recessed portions formed between the plurality of projecting portions.

CROSS REFERENCES TO RELATED APPLICATIONS

The subject matter of application Ser. No. 12/267,091, is incorporatedherein by reference. The present application is a Continuation of U.S.Ser. No. 12/267,091, filed Nov. 7, 2008, which claims priority toJapanese Patent Application JP 2007-305612 filed in the Japan PatentOffice on Nov. 27, 2007, the entire contents of which being incorporatedherein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a display device having a backlight andan optical device applicable to the same and other devices.

2. Description of the Related Art

Display devices are known which have a backlight using two or more lightsources in combination. For example, Japanese Patent Laid-Open No.2005-275644 relates to a touch panel liquid crystal display device. Inthis display device, the backlight radiates visible and invisible lightonto the display panel. The image is displayed with the visible light.The detection target (e.g., user's finger) in proximity to the displaypanel is detected by detecting, with sensors, the invisible lightreflected by the detection target. This document discloses the backlightconfiguration using two types of light sources in combination, i.e.,visible and invisible light sources.

SUMMARY OF THE INVENTION

One of the possible methods of radiating visible and invisible lightonto the display panel by using visible and invisible light sources incombination is to arrange a plurality of LEDs (Light Emitting Diode)adapted to produce visible light and a plurality of LEDs adapted toproduce invisible light along the side surface of a light guide plateopposed to the rear surface of the display panel in a so-calledsidelight-type backlight. However, it is difficult to arrange, in alimited space, namely, on the side surface of the light guide plate, asufficient number of visible light LEDs in consideration of the displaybrightness required for visibility and a sufficient number of invisiblelight LEDs in consideration of the sensor sensitivity.

A possible solution to the above problem would be to arrange the visibleand invisible light LEDs out of alignment with each other in thedirection in proximity to but spaced from the side surface of the lightguide plate. In this case, however, it is difficult to distributevisible and invisible light uniformly over the light guide plate due tovarious circumstances. For example, the invisible (or visible) lightLEDs spaced from the side surface of the light guide plate cannot causethe produced light to efficiently fall upon the light guide plate. As aresult, it is necessary to increase the number of LEDs so as todistribute invisible (or visible) light sufficiently over the lightguide plate, thus resulting in increased power consumption.

It should be noted that two different light sources often requiredifferent numbers of LEDs. In a touch panel display device designed todisplay an image with visible light and detect the user operations withinvisible light, for example, the invisible light LEDs are consideredsmaller in number than the visible light LEDs.

It is an object of the present invention to provide a display device andoptical device which can uniformly radiate light of differentwavelengths while at the same time offering a higher degree of freedomin the arrangement of a plurality of light sources different inwavelength and number.

The display device according to an embodiment of the present inventionincludes a visual target and a backlight adapted to illuminate thevisual target from the rear. The backlight includes a plurality of firstlight sources, second light sources smaller in number than the firstlight sources and a light guide plate. The plurality of first lightsources are disposed on the rear of the visual target and on one side ofa given direction along the rear surface of the visual target to producelight of a first wavelength. The second light sources are disposed onthe rear of the visual target and on the one side of the given directionto produce light of a second wavelength different from the firstwavelength. The light guide plate is disposed to be opposed to the rearsurface of the visual target. The light guide plate radiates the light,produced by the first and second light sources, across the rear surfaceof the visual target while at the same time guiding the light towardanother side of the given direction. The light guide plate has aplurality of projecting portions on a side surface portion thereof uponwhich the light, produced by the plurality of first and second lightsources, is incident. The projecting portions are arranged, along theside surface portion and project toward the one side of the givendirection. The plurality of first light sources are disposed to beopposed to the tip surfaces of the plurality of projecting portions. Thesecond light sources are disposed to be opposed to the bottom surfacesof recessed portions formed between the plurality of projectingportions.

The display device preferably includes a plurality of sensors. Thesensors are preferably disposed in a distributed manner at positions ona plane overlapping the visual target and light guide plate. The sensorspreferably detect the light of the second wavelength which has passedthrough the visual target from the rear side and has been reflected by adetection target which is located on the front of the visual target.

The first wavelength is preferably a visible light wavelength, and thesecond wavelength is an invisible light wavelength.

Projections and recesses are preferably formed on the tip surfaces ofthe plurality of projecting portions and the bottom surfaces of therecessed portions to scatter light. The projections and recesses on thebottom surfaces of the recessed portions are preferably formed smallerthan those on the tip surfaces of the plurality of projecting portions.

A light-scattering substance is preferably mixed in the light guideplate. The light-scattering substance is preferably relatively higher inconcentration in the region surrounding the region with which the visualtarget coincides and to which the second light sources are opposed asseen in plan view.

The optical device according to an embodiment of the present inventionincludes a plurality of first light sources, second light sourcessmaller in number than the first light sources and a light guide member.The plurality of first light sources produce light of a firstwavelength. The second light sources produce light of a secondwavelength different from the first wavelength. The light guide memberguides the light, produced by the first and second light sources, in agiven direction. The light guide member has a plurality of projectingportions on a surface portion thereof upon which the light from theplurality of first light sources and from the second light sources isincident. The plurality of projecting portions are arranged along thesurface portion. The plurality of first light sources are disposed to beopposed to the tip surfaces of the plurality of projecting portions. Thesecond light sources are disposed to be opposed to the bottom surfacesof recessed portions formed between the plurality of projectingportions.

The present invention permits uniform radiation of light of differentwavelengths while at the same time offering a higher degree of freedomin the arrangement of a plurality of light sources different inwavelength and number.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A to 1C are schematic configuration diagrams of a display deviceaccording to an embodiment of the present invention;

FIGS. 2A and 2B are plan views illustrating, in enlarged fashion, thearea surrounding a light source section of the display device shown inFIG. 1;

FIG. 3 is a plan view illustrating the essential portion of amodification example of the present invention; and

FIG. 4 is a plan view illustrating the essential portion of anothermodification example of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1A is an exploded perspective view illustrating the schematicconfiguration of a display device 5 according to a first embodiment ofthe present invention. It should be noted that some members andcomponents are omitted in FIGS. 1A to 10.

The display device 5 is a so-called touch sensor display device. As aresult, the display device 5 can not only display an image on a displaysurface 9 a which is shown on the top side of the page, but also detecta detection target such as user's finger in contact with or proximity tothe display surface 9 a. It should be noted that the top side of FIGS.1A to 10 may be referred to as the front side or front, and the bottomside thereof as the rear side, back or rear in the description givenhereinafter.

A description will be given first of the configuration of the displaydevice 5 for displaying an image.

The display device 5 includes, for example, a transmissive orsemi-transmissive liquid crystal display device and has a display panel9 and backlight 11. The display panel 9 displays an image. The backlight11 illuminates the display panel 9 from the rear thereof.

The display panel 9 includes, for example, an array substrate 17, CFsubstrate 19, liquid crystal 15 (refer to FIG. 1C) filled into the gapbetween the two substrates, incoming-side polarizing plate 21 andoutgoing-side polarizing plate 23. The incoming-side polarizing plate 21is stacked on the back of the array substrate 17. The outgoing-sidepolarizing plate 23 is stacked on the front of the CF (color filter)substrate 19. The display panel 9 has a plurality of pixels 25. Thedisplay panel 9 displays an image on the display surface 9 a bycontrolling the light intensity from the backlight 11 passing througheach of the plurality of pixels 25. It should be noted that the displaysurface 9 a includes, for example, an unshown light transmitting layerwhich is stacked on the incoming-side polarizing plate 21 andoutgoing-side polarizing plate 23.

The display panel 9 is electrically connected to a circuit substrate 33via a TAB 31. The circuit substrate 33 has, for example, a controlsection (CPU (Central Processing Unit)) 34 which includes ICs(Integrated Circuit) and other components. The control section 34transmits electric signals to the display surface 9 a so as to displayan image. The control section 34 also receives electric signals from thedisplay panel 9 to detect the user operation performed on the displaysurface 9 a.

The backlight 11 includes, for example, a sidelight-type backlight andhas a light source section 27 and light guide plate 29. The light sourcesection 27 produces visible and invisible light. The light guide plate29 guides visible light from the light source section 27 toward the rearof the display panel 9 and radiates visible light across the rearsurface of the display panel 9. The light source section 27 is disposedon the rear of the display panel 9 and on one side of a given directionalong the rear surface of the display panel 9 (on the left side of FIG.1A). The light guide plate 29 is formed in the approximate shape of arectangular plate and disposed to be opposed to the rear surface of thedisplay panel 9. The light guide plate 29 guides the light from thelight source section 27, disposed on one side of The light guide plate29, toward another side of the given direction along the rear surface ofthe display panel 9 (on the right side of FIG. 1A).

FIG. 1B is a plan view schematically illustrating the pixel 25.

The pixel 25 includes a plurality of subpixels 35R, 35G and 35B(hereinafter may be abbreviated as R, G and B) respectively associatedwith a plurality of (e.g., three) colors (light wavelengths). Forexample, the subpixels 35R, 35G and 35B are associated with red (R),green (G) and blue (B), respectively. The intensity of light ofdifferent colors from the three subpixels 35 is adjusted. As a result,an arbitrary color is visually identified as the color of the pixel 25,and an image is displayed on the display surface 9 a.

FIG. 1C is a diagram schematically illustrating the section along lineIIc-IIc of FIG. 1B.

A pixel electrode 39, incoming-side planarizing layer 41 andincoming-side orientation film 43 are, for example, stacked one over theother on the surface of the array substrate 17 facing the liquid crystal15 under the subpixel 35. The pixel electrode 39 is provided for each ofthe subpixels 35. The incoming-side planarizing layer 41 smoothes outthe projections and recesses resulting, for example, from the pixelelectrode 39. The incoming-side orientation film 43 orients the liquidcrystal 15. Further, a color filter 45, outgoing-side planarizing layer47, common electrode 49 and outgoing-side orientation film 51 arestacked one over the other on the surface of the CF substrate 19 facingthe liquid crystal 15 under the subpixel 35. The color filter 45transmits only light of the color associated with the subpixel 35. Theoutgoing-side planarizing layer 47 smoothes out the projections andrecesses resulting, for example, from the color filter 45. The commonelectrode 49 is provided commonly for the plurality of subpixels 35. Theoutgoing-side orientation film 51 orients the liquid crystal 15.

It should be noted that the array substrate 17 has, in addition to theabove, data electrodes (may be typically referred to as X electrodes,data signal lines or source signal lines), TFT (Thin Film Transistor)elements which function as switching elements adapted to drive theliquid crystal, and capacitors serving as signal holding capacitancesfor active matrix operation and other components. However, theillustration thereof is omitted.

When a voltage is applied between the pixel electrode 39 and commonelectrode 49 under the subpixel 35, the liquid crystal 15 is oriented ina direction different from that regulated by the incoming-side andoutgoing-side orientation films 43 and 51. The liquid crystal 15 isoriented at an angle appropriate to the voltage applied. This controlsthe optical rotation angle of the polarized light which travels from theincoming-side polarizing plate 21 to the outgoing-side polarizing plate23. This, in turn, adjusts the light intensity of the subpixel 35.

A description will be given next of the configuration of the displaydevice 5 for detecting user operations.

As illustrated in FIG. 1B, the pixel 25 has a detection section 37adapted to detect light falling upon the pixel 25 from the front of thedisplay surface 9 a. It should be noted that the arrangement of thesubpixels 35 and detection section 37, as seen in plan view, may be setas appropriate. FIG. 1B illustrates the case in which the subpixels 35and detection section 37 are arranged in a rectangular manner.

As illustrated in FIG. 1C, a photoelectric sensor 48 is provided, forexample, under the detection section 37 in place of the pixel electrode39 provided under the subpixel 35. The photoelectric sensor 48 convertsreceived light into an electric signal. The photoelectric sensor 48includes, for example, a PIN or PDN photodiode made of a-Si or u-Si. Thephotoelectric sensor 48 is formed, for example, by photolithography ofthe array substrate 17 as with TFT elements and other components.

It should be noted that the color filter 45 may or may not be providedunder the detection section 37. Further, if the photoelectric sensor 48detects user operations by using infrared light as mentioned later, anIR filter adapted to pass only infrared light may be provided, ratherthan the color filter 45, in order to provide a higher S/N ratio.

FIGS. 2A and 2B are plan views illustrating, in enlarged fashion, thearea in the neighborhood of the light source section 27 of the backlight11. It should be noted that FIG. 2A illustrates the manner in whichvisible light VL is radiated from the light source section 27, and FIG.2B the manner in which invisible light IL is radiated therefrom.

The light source section 27 includes a plurality of visible light LEDs53 adapted to produce the visible light VL and a plurality of invisiblelight LEDs 55 adapted to produce the invisible light.

The visible light VL is, for example, white light. The invisible lightIV is, for example, infrared light. According to CIE (CommissionInternational de l'Eclairrage), the boundary in wavelength betweenultraviolet light (also an example of invisible light) and visible lightis 360 nm to 400 nm, and that between visible light and infrared lightis 760 nm to 830 nm. Practically, however, light having a wavelength of350 nm or less may be considered ultraviolet light, and that having awavelength of 700 nm or more infrared light.

The visible and invisible light LEDs 53 and 55 each include, forexample, a reflector-equipped chip LED. These LEDs are formed generallyin a rectangular shape as a whole and have radiation surfaces 53 a and55 a on one surface of the rectangle (bottom side of the page in FIGS.2A and 2B). Each of the radiation surfaces 53 a and 55 a is slightlysmaller than the surface of the visible LED 53 or invisible LED 55 wherethe radiation surfaces 53 a or 55 a is provided. The visible andinvisible light LEDs 53 and 55 are disposed so that the radiationsurfaces 53 a and 55 a are respectively opposed to a side surfaceportion 29 a of the light guide plate 29. The plurality of invisiblelight LEDs 55 are smaller in number than the visible light LEDs 53.FIGS. 2A and 2B illustrate the case in which the seven visible lightLEDs 53 and two invisible light LEDs 55 are provided. The visible andinvisible light LEDs 53 and 55 may be sized as appropriate. In FIGS. 2Aand 2B, the visible and invisible light LEDs 53 and 55 are generallyequally sized.

The light guide plate 29 includes, for example, transparent acrylicplate and guides light from the light source section 27 along its frontand rear surfaces while totally reflecting the light by these surfaces.An unshown dot pattern (a plurality of projecting portions) is, forexample, provided on the rear surface of the light guide plate 29. Thedot pattern is formed integrally with the light guide plate 29 or formedby a separate member therefrom. The guided light is scattered by the dotpattern and radiated onto the display panel 9. It should be noted that areflecting sheet adapted to reflect light may be provided on the rearside of the light guide plate 29, and a diffusing sheet or prism sheeton the front side thereof.

The light guide plate 29 has a plurality of projecting portions 29 bprojecting toward the light source section 27. The plurality ofprojecting portions 29 b are arranged on the side surface portion 29 aupon which the light from the light source section 27 falls. Theprojecting portions 29 b are arranged, as seen in plan view, along theside surface portion 29 a. The plurality of projecting portions 29 b areformed, for example, in the same shape and size and arranged at constantintervals. The plurality of projecting portions 29 b are, for example,rectangular in shape. A plurality of recessed portions 29 c are formedbetween the plurality of projecting portions 29 b, by the projectingportions 29 b.

The plurality of visible light LEDs 53 are disposed to be opposed to thetip surfaces of the plurality of projecting portions 29 b. Further, theplurality of invisible light LEDs 55 are disposed to be opposed to thebottom surfaces of the plurality of recessed portions 29 c. In otherwords, the plurality of visible light LEDs 53 are arranged, as seen inplan view, in the direction along the side surface portion 29 a of thelight guide plate 29. The plurality of invisible light LEDs 55 aredisposed, as seen in plan view, not only more toward the bottom side ofthe page in FIGS. 2A and 2B (light guiding side of the light guide plate29) than the plurality of visible light LEDs 53 but also between theplurality of visible light LEDs 53 in the direction along the sidesurface portion 29 a. That is, the plurality of visible and invisiblelight LEDs 53 and 55 are selectively arranged in two columns in analternating manner.

It should be noted that the recessed portion 29 c is sized, for example,slightly larger than the size into which the invisible light LED 55 fitsor the size of the invisible light LED 55. The tip surface of theprojecting portion 29 b is sized, for example, equal to or slightlylarger than the radiation surface 53 a of the visible light LED 53.

According to the above embodiment, the display device 5 includes thedisplay panel 9 and backlight 11. The backlight 11 illuminates thedisplay panel 9 from the rear thereof. The backlight 11 includes theplurality of visible light LEDs 53, the invisible light LEDs 55 smallerin number than the plurality of visible light LEDs 53, and the lightguide plate 29. The plurality of visible light LEDs 53 are disposed onthe rear of the display panel 9 and on one side (left side of the pagein FIGS. 1A to 1C) of a given direction along the rear surface of thedisplay panel 9 (horizontal direction of the page in FIGS. 1A to 1C) toproduce light of a visible wavelength (in the visible spectrum). Theinvisible light LEDs 55 are disposed on the rear of the display panel 9and on the one side (left side of the page in FIGS. 1A to 1C) of thegiven direction to produce light of an invisible wavelength (in theinvisible spectrum). The light guide plate 29 is disposed to be opposedto the rear surface of the display panel 9. The light guide plate 29radiates the light, produced by the first and second light sources,across the rear surface of the display panel 9 while at the same timeguiding the light toward another side of the given direction (right sideof the page in FIGS. 1A to 1C). The light guide plate 29 has theplurality of projecting portions 29 b on the side surface portion 29 aupon which the light, produced by the plurality of visible and invisiblelight LEDs 53 and 55, falls. The projecting portions 29 b are arranged,as seen in plan view, along the side surface portion 29 a and projecttoward one side of a given direction (top side of the page in FIGS. 2Aand 2B). The plurality of visible light LEDs 53 are disposed to beopposed to the tip surfaces of the plurality of projecting portions 29b. The plurality of invisible light LEDs 55 are disposed to be opposedto the bottom surfaces of the recessed portion 29 c formed between theplurality of projecting portions 29 b. Thus, the present embodimentpermits uniform radiation of light of different wavelengths while at thesame time offering a higher degree of freedom in the arrangement of thevisible and invisible light LEDs 53 and 55 which differ in wavelengthand number from each other. More specifically, the present embodiment isconfigured as follows.

As illustrated in FIG. 2A, the visible light VL from the visible lightLED 53 is guided by the projecting portion 29 b to reach a main bodyportion 29 m of the light guide plate 29. Upon reaching the main bodyportion 29 m, the visible light VL is guided toward the bottom side ofthe page in FIGS. 2A and 2B while at the same time spreading out at aconstant angle θ1 in the horizontal direction of the page in FIGS. 2Aand 2B (in the direction of arrangement of the plurality of projectingportions 29 b). Of the light falling upon the projecting portion 29 bfrom the visible light LED 53, the light significantly inclined relativeto the projecting portion 29 b does not reach the main body portion 29 mbecause it is emitted from the outer perimeter surface (interface)between the plurality of projecting portions 29 b. As a result, theangle θ1 at which the visible light VL, which has reached the main bodyportion 29 m, spreads out is relatively small. However, the plurality ofvisible light LEDs 53 are provided in large number. Therefore, thevisible light VL spreads out uniformly over the area opposed to thedisplay panel 9 in the horizontal direction of the page in FIGS. 2A and2B.

As illustrated in FIG. 2B, the invisible light IL from the invisiblelight LED 55 falls directly upon the main body portion 29 m of the lightguide plate 29. The invisible light IL is guided toward the bottom sideof the page in FIGS. 2A and 2B while at the same time spreading out at aconstant angle θ2 in the horizontal direction of the page in FIGS. 2Aand 2B (in the direction of arrangement of the plurality of projectingportions 29 b). Unlike the visible light VL, all the light from theinvisible light LED 55 basically falls upon the main body portion 29 m,irrespective of its angle. Therefore, the angle θ2 at which theinvisible light IL spreads out on the main body portion 29 m is largerthan the angle θ1 at which the visible light VL spreads out. As aresult, the invisible light LEDs 55 are smaller in number than thevisible light LEDs 53. However, the invisible light IL spreads outuniformly over the area opposed to the display panel 9 in the directionof arrangement of the plurality of projecting portions 29 b.

Therefore, the arrangement of the plurality of visible and invisiblelight LEDs 53 and 55 at different distances from the side surfaceportion 29 a has been previously difficult to achieve due to thedifficulty involved in uniformly guiding light. However, thisarrangement, in other words, the arrangement of the plurality of visibleand invisible light LEDs 53 and 55 in two columns, is possible. As aresult, the visible and invisible light LEDs 53 and 55 can be lessspaced from each other or located to partially coincide with each otherin the direction along the side surface portion 29 a (in the horizontaldirection of the page in FIGS. 2A and 2B). This makes it possible toprovide a large number of LEDs on the side surface portion 29 a.Further, the visible and invisible light LEDs, different in optimalpower from each other, can be each arranged in an optimal number.

In the above embodiment, the backlight 11 is an example of the opticaldevice (illumination device) of the present invention, the display panel9 an example of the visual target thereof, the visible light LED 53 anexample of the first light source thereof, the invisible light LED 55 anexample of the second light source thereof, the visible light an exampleof light of the first wavelength thereof, the invisible light an exampleof light of the second wavelength thereof, the light guide plate 29 anexample of the light guide member thereof, and the side surface portion29 a of the light guide plate 29 an example of the side surface andsurface portions thereof.

FIG. 3 is a plan view illustrating the essential portion of amodification example of the present invention.

A light guide plate 129 in the modification example has projections andrecesses formed on the tip surface of a projecting portion 129 b and onthe bottom surface of a recessed portion 129 c to scatter light. Theprojections and recesses on the bottom surface of the recessed portion129 c are formed smaller than those on the tip surface of the projectingportion 129 b.

Therefore, the invisible light IL falling upon the bottom surface of therecessed portion 129 c is more likely to spread out in the horizontaldirection of the page in FIG. 3 (direction along a side surface portion129 a as seen in plan view) in the light guide plate 129 than thevisible light VL. As a result, although the invisible light LEDs 55 aresmaller in number than the visible light LEDs 53, the invisible light ILcan be guided as uniformly as the visible light VL.

It should be noted that projections and recesses may be disposedtwo-dimensionally as seen from above the page in FIG. 3. Alternatively,projecting rims (grooves), long in the direction passing through thepage, may be disposed one-dimensionally in the horizontal direction ofthe page in FIG. 3. Projections and recesses may be sized and spaced asappropriate.

FIG. 4 is a plan view illustrating the essential portion of anothermodification example of the present invention.

A light-scattering substance 229 f adapted to scatter light is mixed ina light guide plate 229 of another modification example. For example,the light guide plate 229 includes a so-called highly scattering opticaltransmission polymer. That is, the light guide plate 229 is formed bymixing a polymer serving as the light-scattering substance 229 f with anacrylic resin serving as the base material. The polymer has a refractiveindex different from that of the acrylic resin. The light-scatteringsubstance 229 f is relatively high in concentration in a surroundingarea 229 g around an opposed area 229 h which coincides with the displaypanel 9 and to which the invisible light LED 55 is opposed. It should benoted that if the plurality of invisible light LEDs 55 are provided, thesurrounding area 229 g is located between the invisible light LEDs 55.FIG. 4 illustrates the case in which the invisible light LEDs 55 aredisposed with a projecting portion 229 b therebetween.

The invisible light LEDs 55 are small in number. Therefore, theintensity of the invisible light IL is likely low in the surroundingarea 229 b. As a result, the detection sensitivity of the detectiontarget using the invisible light IL may be uneven in the plane directionof the display panel 9.

However, if the concentration of the light-scattering substance 229 f inthe surrounding area 229 g is set relatively high as described above,the intensity of light emitted toward the display panel 9 accounts for alarge percentage of the intensity of light guided into the light guideplate 29 in the surrounding area 229 g. This evens out the intensity oflight emitted toward the display panel 9 across the opposed area 229 hand surrounding area 229 g, thus suppressing the uneven detection.

The present invention is not limited to the above embodiment ormodification examples, but may be carried out in various forms. Further,the forms shown in the embodiment and modification examples may becombined as appropriate.

The display device according to the present invention may be applied toall kinds of electronic equipment. For example, the display deviceaccording to the present invention may be applied to mobile phones,digital cameras, PDAs, laptop PCs, gaming machines, television sets, carnavigators and ATMs.

The display device according to the present invention is not limited tothat having a display panel adapted to display an image. In other words,the visual target viewed by the user is not limited to a display panel.For example, the visual target may be a plurality of keys or a piece ofpaper with maps or other graphics drawn thereon.

If the display device according to the present invention has a displaypanel, the display panel is not limited to that which displays an imageby means of a plurality of pixels. For example, the display panel may bea segment display device. The display panel is not limited to a liquidcrystal display device, but may be, for example, an organic EL displaydevice or electronic paper (e-paper).

There may be the only one or plurality of second light sources so longas the second light sources are smaller in number than first lightsources. The combination of the first and second wavelengths is notlimited to the combination of visible and invisible light wavelengths.For example, the first and second wavelengths may be two differentwavelengths in the visible spectrum. Alternatively, the first wavelengthmay be an invisible light wavelength, and the second wavelength avisible light wavelength. Further, the invisible light is not limited toinfrared light, but may be ultraviolet light. The first and second lightsources may produce light of a single wavelength as does a laser beamsource. Alternatively, these light sources may produce light in a givenrange of wavelengths as does a white light source. If the first andsecond light sources each produce light in a range of wavelengths, theranges of wavelengths of the first and second light sources maypartially overlap each other.

The combination of applications of light of the first and secondwavelengths is not limited to the combination of the illumination of thevisual target and the detection of the detection target. For example,two different wavelengths in the visible spectrum may be used as thefirst and second wavelengths, in other words, the first and second lightsources may be used which produce light of different colors, so that theillumination color can be changed by controlling the balance in lightintensity between light from the first and second light sources.

The arrangement and density of the plurality of sensors may be set asappropriate. Further, the arrangement and density thereof may be locallychanged. One sensor need not be provided for each pixel. For example,the sensors may be distributed in such a manner that a common sensor isprovided for a plurality but a small number of pixels such as two tofive pixels. The sensors may be provided on the front or back of thevisual target (including the display panel).

The light guide member is not limited to that in the form of a plate(light guide plate), but may be in the form of a long rectangularparallelepiped or cube. Further, the light guide member is not limitedto that which emits light in the direction intersecting the direction inwhich light is guided (top side of the page in FIGS. 1A to 1C in theembodiment) while at the same time guiding the light toward the lightguiding direction (right side of the page in FIGS. 1A to 1C in theembodiment). The light guide member may emit light in the light guidingdirection.

The plurality of projecting portions on the light guide member may beshaped as appropriate and are not limited to a rectangular shape. Forexample, the projecting portions may be formed so as to increase indiameter toward their tip. In this case, the first light sources opposedto the tip surfaces of the projecting portions can be increased in size.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

1. A display device comprising: a light guide plate to radiate thelight, produced by first and second light sources, toward a displaysurface, wherein the light guide plate has a plurality of projectingportions at a side portion thereof, the plurality of first light sourcesare disposed to be at corresponding surfaces of the plurality ofprojecting portions, and the second light sources are disposed atcorresponding recessed portions between the plurality of projectingportions.
 2. The display device of claim 1 further comprising aplurality of sensors disposed in a distributed manner at positions on aplane overlapping the light guide plate, the sensors being adapted todetect the light of the second wavelength.
 3. The display device ofclaim 2, wherein the first wavelength is a visible light wavelength, andthe second wavelength is an invisible light wavelength.
 4. The displaydevice of claim 1, wherein projections and recesses are formed on theplurality of projecting portions and the bottom surfaces of the recessedportions to scatter light, and the projections and recesses on thebottom surfaces of the recessed portions are formed smaller than thoseon the tip surfaces of the plurality of projecting portions.
 5. Thedisplay device of claim 1, wherein a light-scattering substance is mixedin the light guide plate.
 6. An optical device comprising: a pluralityof first light sources adapted to produce light of a first wavelength;second light sources adapted to produce light of a second wavelengthdifferent from the first wavelength and smaller in number than the firstlight sources; and a light guide member adapted to guide the light,produced by the first and second light sources, in a given direction,wherein the light guide member has a plurality of projecting portions ata side portion thereof upon which the light from the plurality of firstlight sources and from the second light sources is incident, theplurality of first light sources are disposed at corresponding surfacesof the plurality of projecting portions, and the second light sourcesare disposed at corresponding surfaces of recessed portions formedbetween the plurality of projecting portions.